Layer 2 Virtual Private Networks Using BGP for Auto-discovery
and Signaling
Juniper Networks1194 N. Mathilda Ave.SunnyvaleCA94089USkireeti@juniper.netCisco Systems3750 Cisco WaySan JoseCA95134USAbhupesh@cisco.comJuniper Networks1194 N. Mathilda Ave.SunnyvaleCA94089UScherukuri@juniper.net
Internet
BGP L2VPN discovery signaling pseudowire
Layer 2 Virtual Private Networks (L2VPNs) based on Frame
Relay or ATM circuits have been around a long time; more
recently, Ethernet VPNs, including Virtual Private LAN
Service, have become popular. Traditional L2VPNs often
required a separate Service Provider infrastructure for each
type, and yet another for the Internet and IP VPNs. In
addition, L2VPN provisioning was cumbersome. This document
presents a new approach to the problem of offering L2VPN
services where the L2VPN customer's experience is virtually
identical to that offered by traditional Layer 2 VPNs, but
such that a Service Provider can maintain a single network
for L2VPNs, IP VPNs and the Internet, as well as a common
provisioning methodology for all services.
The earliest Virtual Private Networks (VPNs) were based on Layer 2
circuits: X.25, Frame Relay and ATM (see ).
More recently, multipoint VPNs based on Ethernet Virtual Local
Area Networks (VLANs) and Virtual Private LAN Service (VPLS)
( and ) have
become quite popular. In contrast, the VPNs described in this
document are point-to-point, and usually called Virtual Private
Wire Service (VPWS). All of these come under the classification
of Layer 2 VPNs (L2VPNs), as the customer to Service Provider (SP)
hand-off is at Layer 2.
There are at least two factors that adversely affected the cost of
offering L2VPNs. The first is that the easiest way to offer a
L2VPN of a given type of Layer 2 was over an infrastructure of the
same type. This approach required that the Service Provider build
a separate infrastructure for each Layer 2 encapsulation -- e.g.,
an ATM infrastructure for ATM VPNs, an Ethernet infrastructure for
Ethernet VPNs, etc. In addition, a separate infrastructure was
needed for the Internet and IP VPNs (, and possibly yet another
for voice services. Going down this path meant a proliferation of
networks.
The other is that each of these networks had different
provisioning methodologies. Furthermore, the provisioning of a
L2VPN was fairly complex. It is important to distinguish between
a single Layer 2 circuit, which connects two customer sites, and a
Layer 2 VPN, which is a set of circuits that connect sites
belonging to the same customer. The fact that two different
circuits belonged to the same VPN was typically known only to the
provisioning system, not to the switches offering the service;
this complicated the setting up, and subsequently, the
troubleshooting, of a L2VPN. Also, each switch offering the
service had to be provisioned with the address of every other
switch in the same VPN, requiring, in the case of full-mesh VPN
connectivity, provisioning proportional to the square of the
number of sites. This made full-mesh L2VPN connectivity
prohibitively expensive for the SP, and thus in turn for
customers. Finally, even setting up a individual circuit often
required the provisioning of every switch along the path.
Of late, there has been much progress in network "convergence",
whereby Layer 2 traffic, Internet traffic and IP VPN traffic can
be carried over a single, consolidated network infrastructure
based on IP/MPLS tunnels; this is made possible by techniques such
as those described in ,
, , and
for Layer 2 traffic, and
for IP VPN traffic. This development
goes a long way toward addressing the problem of network
profileration. This document goes one step further and shows how
a Service Provider can offer Layer 2 VPNs using protocol and
provisioning methodologies similar to that used for VPLS
() and IP VPNs (),
thereby achieving a significant degree of operational convergence
as well. In particular, all of these methodologies include the
notion of a VPN identifier that serves to unify components of a
given VPN, and the concept of auto-discovery, which simplifies the
provisioning of dense VPN topologies (for example, a full mesh).
In addition, similar techniques are used in all of the
above-mentioned VPN technologies to offer inter-AS and
inter-provider VPNs (i.e., VPNs whose sites are connected to
multiple Autonomous Systems (ASs) or service providers).
Technically, the approach proposed here uses the concepts and
solution and described in , which
describes a method for VPLS, a particular form of a Layer 2 VPN.
That document in turn borrowed much from .
This includes the use of BGP for auto-discovery and
"demultiplexor" (see below) exchange, and the concepts of Route
Distinguishers to make VPN advertisements unique, and Route
Targets to control VPN topology. In addition, all three
documents share the idea that routers not directly connected to
VPN customers should carry no VPN state, restricting the
provisioning of individual connections to just the edge devices.
This is achieved by using tunnels to carry the data, with a
demultiplexor that identifies individual VPN circuits. These
tunnels could be based on MPLS, GRE, or any other tunnel
technology that offers a demultiplexing field; the signaling of
these tunnels is outside the scope of this document. The
specific approach taken here is to use an MPLS label as the
demultiplexor.
Layer 2 VPNs typically require that all sites in the VPN connect
to the SP with the same Layer 2 encapsulation. To ease this
restriction, this document proposes a limited form of Layer 2
interworking, by restricting the Layer 3 protocol to IP only
(see Section 5).
It may be instructive to compare the approach in and (these are the
IETF-approved technologies for the functions described in this
document, albeit using two separate protocols) with the one
described here. Devices implementing the solution described in
this document must also implement the approach in and .
The rest of this section discusses the relative merits of Layer
2 and Layer 3 VPNs. Section 3 describes the operation of a
Layer 2 VPN. Section 5 describes IP-only Layer 2 interworking.
Section 6 describes how the L2 packets are transported across
the SP network.
The terminology used is from and
, and is briefly repeated here. A
"customer" is a customer of a Service Provider seeking to
interconnect their various "sites" (each an independent network)
at Layer 2 through the Service Provider's network, while
maintaining privacy of communication and address space. The
device in a customer site that connects to a Service Provider
router is termed the CE (customer edge) device; this device may be
a router or a switch. The Service Provider router to which a CE
connects is termed a PE. A router in the Service Provider's
network which doesn't connect directly to any CE is termed
P. Every pair of PEs is connected by a "tunnel"; within a tunnel,
VPN data is distinguished by a "demultiplexor", which in this
document is an MPLS label.
Each CE within a VPN is assigned a CE ID, a number that uniquely
identifies a CE within an L2 VPN. More accurately, the CE ID
identifies a physical connection from the CE device to the PE,
since a CE may be connected to multiple PEs (or multiply connected
to a PE); in such a case, the CE would have a CE ID for each
connection. A CE may also be part of many L2 VPNs; it would need
one (or more) CE ID(s) for each L2 VPN of which it is a member.
The number space for CE IDs is scoped to a given VPN.
In the case of inter-Provider L2 VPNs, there needs to be some
coordination of allocation of CE IDs. One solution is to allocate
ranges for each SP. Other solutions may be forthcoming.
Within each physical connection from a CE to a PE, there may be
multiple virtual circuits. These will be referred to as
Attachment Circuits (ACs), following .
Similarly, the entity that connects two attachment circuits across
the Service Provider network is called a pseudowire (PW).
A Layer 2 VPN is one where a Service Provider provides Layer 2
connectivity to the customer. The Service Provider does not
participate in the customer's Layer 3 network, in particular, in
the routing, resulting in several advantages to the SP as a
whole and to PE routers in particular.
In a Layer 2 VPN, the Service Provider is responsible for
Layer 2 connectivity; the customer is responsible for Layer 3
connectivity, which includes routing. If the customer says
that host x in site A cannot reach host y in site B, the
Service Provider need only demonstrate that site A is
connected to site B. The details of how routes for host y
reach host x are the customer's responsibility.
Another important factor is that once a PE provides Layer 2
connectivity to its connected CE, its job is done. A
misbehaving CE can at worst flap its interface, but route
flaps in the customer network have little effect on the SP
network. On the other hand, a misbehaving CE in a Layer 3 VPN
can flap its routes, leading to instability of the PE router
or even the entire SP network. Thus, when offering a Layer 3
VPN, a SP should proactively protect itself from Layer 3
instability in the CE network.
Since "traditional" Layer 2 VPNs (i.e., real Frame Relay
circuits connecting sites) are indistinguishable from
tunnel-based VPNs from the customer's point-of-view,
migrating from one to the other raises few issues. Layer 3
VPNs, on the other hand, require a considerable re-design of
the customer's Layer 3 routing architecture. Furthermore,
with Layer 3 VPNs, special care has to be taken that routes
within the traditional VPN are not preferred over the Layer
3 VPN routes (the so-called "backdoor routing" problem,
whose solution requires protocol changes that are somewhat
ad hoc).
In a Layer 2 VPN, the privacy of customer routing is a
natural fallout of the fact that the Service Provider does
not participate in routing. The SP routers need not do
anything special to keep customer routes separate from
other customers or from the Internet; there is no need for
per-VPN routing tables, and the additional complexity this
imposes on PE routers.
Since the Service Provider simply provides Layer 2
connectivity, the customer can run any Layer 3 protocols
they choose. If the SP were participating in customer
routing, it would be vital that the customer and SP both
use the same Layer 3 protocol(s) and routing protocols.
Note that IP-only Layer 2 interworking doesn't have this
benefit as it restricts the Layer 3 to IP only.
In the Layer 2 VPN scheme described below, each PE
transmits a single small chunk of information about
every CE that the PE is connected to to every other PE.
That means that each PE need only maintain a single
chunk of information from each CE in each VPN, and keep
a single "route" to every site in every VPN. This means
that both the Forwarding Information Base and the
Routing Information Base scale well with the number of
sites and number of VPNs. Furthermore, the scaling
properties are independent of the customer: the only
germane quantity is the total number of VPN sites.
This is to be contrasted with Layer 3 VPNs, where each
CE in a VPN may have an arbitrary number of routes that
need to be carried by the SP. This leads to two issues.
First, both the information stored at each PE and the
number of routes installed by the PE for a CE in a VPN
can be (in principle) unbounded, which means in practice
that a PE must restrict itself to installing routes
associated with the VPNs that it is currently a member
of. Second, a CE can send a large number of routes to
its PE, which means that the PE must protect itself
against such a condition. Thus, the SP must enforce
limits on the number of routes accepted from a CE; this
in turn requires the PE router to offer such control.
The scaling issues of Layer 3 VPNs come into sharp focus
at a BGP route reflector (RR). An RR cannot keep all
the advertised routes in every VPN since the number of
routes will be too large. The following
solutions/extensions are needed to address this issue:
1. RRs could be partitioned so that each RR services a
subset of VPNs so that no single RR has to carry all the
routes.
2. An RR could use a preconfigured list of
Route-Targets for its inbound route filtering. The RR
may choose to perform Route Target Filtering, described
in .
Configuring traditional Layer 2 VPNs with dense
topologies was a burden primarily because of the O(n*n)
nature of the task. If there are n CEs in a Frame Relay
VPN, say full-mesh connected, n*(n-1)/2 DLCI PVCs must
be provisioned across the SP network. At each CE, (n-1)
DLCIs must be configured to reach each of the other CEs.
Furthermore, when a new CE is added, n new DLCI PVCs
must be provisioned; also, each existing CE must be
updated with a new DLCI to reach the new CE. Finally,
each PVC requires state in every transit switch.
In our proposal, PVCs are tunnelled across the SP
network. The tunnels used are provisioned independently
of the L2VPNs, using signalling protocols (in case of
MPLS, LDP or RSVP-TE can be used), or set up by
configuration; and the number of tunnels is independent
of the number of L2VPNs. This reduces a large part of
the provisioning burden.
Furthermore, we assume that DLCIs at the CE edge are
relatively cheap; and VPN labels in the SP network are
cheap. This allows the SP to "over-provision" VPNs: for
example, allocate 50 CEs to a VPN when only 20 are
needed. With this over-provisioning, adding a new CE to
a VPN requires configuring just the new CE and its
associated PE; existing CEs and their PEs need not be
re-configured. Note that if DLCIs at the CE edge are
expensive, e.g. if these DLCIs are provisioned across a
switched network, one could provision them as and when
needed, at the expense of extra configuration. This
need not still result in extra state in the SP network,
i.e. an intelligent implementation can allow
overprovisioning of the pool of VPN labels.
Layer 3 VPNs ( in particular) offer a
good solution when the customer traffic is wholly IP, customer
routing is reasonably simple, and the customer sites connect to
the SP with a variety of Layer 2 technologies.
One major restriction in a Layer 2 VPN is that the Layer 2
media with which the various sites of a single VPN connect to
the SP must be uniform. On the other hand, the various sites
of a Layer 3 VPN can connect to the SP with any supported
media; for example, some sites may connect with Frame Relay
circuits, and others with Ethernet.
This restriction of Layer 2 VPN is alleviated by the IP-only
Layer 2 interworking proposed in this document. This comes at
the cost of losing the Layer 3 independence.
A corollary to this is that the number of sites that can be in
a Layer 2 VPN is determined by the number of Layer 2 circuits
that the Layer 2 technology provides. For example, if the
Layer 2 technology is Frame Relay with 2-octet DLCIs, a CE can
connect to at most about a thousand other CEs in a VPN.
Another problem with Layer 2 VPNs is that the CE router in a VPN must
be able to deal with having N routing peers, where N is the number of
sites in the VPN. This can be alleviated by manipulating the
topology of the VPN. For example, a hub-and-spoke VPN architecture
means that only one CE router (the hub) needs to deal with N
neighbors. However, in a Layer 3 VPN, a CE router need only deal
with one neighbor, the PE router. Thus, the SP can offer Layer 3
VPNs as a value-added service to its customers.
Moreover, with Layer 2 VPNs it is up to a customer to build and
operate the whole network. With Layer 3 VPNs, a customer is just
responsible for building and operating routing within each site,
which is likely to be much simpler than building and operating
routing for the whole VPN. That, in turn, makes Layer 3 VPNs more
suitable for customers who don't have sufficient routing expertise,
again allowing the SP to provide added value.
As mentioned later, multicast routing and forwarding is another
value-added service that an SP can offer.
Class-of-Service issues have been addressed for Layer 3 VPNs. Since
the PE router has visibility into the network Layer (IP), the PE
router can take on the tasks of CoS classification and routing. This
restriction on Layer 2 VPNs is again eased in the case of IP-only
Layer 2 interworking, as the PE router has visibility into the
network Layer (IP).
There are two aspects to multicast routing that we will consider. On
the protocol front, supporting IP multicast in a Layer 3 VPN requires
PE routers to participate in the multicast routing instance of the
customer, and thus keep some related state information.
In the Layer 2 VPN case, the CE routers run native multicast routing
directly. The SP network just provides pipes to connect the CE
routers; PEs are unaware whether the CEs run multicast or not, and
thus do not have to participate in multicast protocols or keep
multicast state information.
On the forwarding front, in a Layer 3 VPN, CE routers do not
replicate multicast packets; thus, the CE-PE link carries only one
copy of a multicast packet. Whether replication occurs at the
ingress PE, or somewhere within the SP network depends on the
sophistication of the Layer 3 VPN multicast solution. The simple
solution where a PE replicates packets for each of its CEs may place
considerable burden on the PE. More complex solutions may require
VPN multicast state in the SP network, but may significantly reduce
the traffic in the SP network by delaying packet replication until
needed.
In a Layer 2 VPN, packet replication occurs at the CE. This has
the advantage of distributing the burden of replication among the
CEs rather than focusing it on the PE to which they are attached,
and thus will scale better. However, the CE-PE link will need to
carry the multiple copies of multicast packets. In the case of
Virtual Private LAN Service (a specific type of L2 VPN; see
), however, the CE-PE link need transport
only one copy of a multicast packet.
Thus, just as in the case of unicast routing, the SP has the choice
to offer a value-added service (multicast routing and forwarding) at
some cost (multicast state and packet replication) using a Layer 3
VPN, or to keep it simple and use a Layer 2 VPN.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in .
The following contributed to this document.
Manoj Leelanivas, Juniper Networks
Quaizar Vohra, Juniper Networks
Javier Achirica, Consultant
Ronald Bonica, Juniper Networks
Dave Cooper, Global Crossing
Chris Liljenstolpe, Telstra
Eduard Metz, KPN Dutch Telecom
Hamid Ould-Brahim, Nortel
Chandramouli Sargor
Himanshu Shah, Ciena
Vijay Srinivasan
Zhaohui Zhang, Juniper Networks
The following simple example of a customer with 4 sites connected to
3 PE routers in a Service Provider network will hopefully illustrate
the various aspects of the operation of a Layer 2 VPN. For
simplicity, we assume that a full-mesh topology is desired.
In what follows, Frame Relay serves as the Layer 2 media, and each
CE has multiple DLCIs to its PE, each to connect to another CE in
the VPN. If the Layer 2 media were ATM, then each CE would have
multiple VPI/VCIs to connect to other CEs. For PPP and Cisco HDLC,
each CE would have multiple physical interfaces to connect to other
CEs. In the case of IP-only Layer 2 interworking, each CE could have
a mix of one or more of the above Layer 2 media to connect to other
CEs.
Consider a Service Provider network with edge routers PE0, PE1, and
PE2. Assume that PE0 and PE1 are IGP neighbors, and PE2 is more than
one hop away from PE0.
Suppose that a customer C has 4 sites S0, S1, S2 and S3 that C
wants to connect via the Service Provider's network using Frame
Relay. Site S0 has CE0 and CE1 both connected to PE0. Site S1 has
CE2 connected to PE0. Site S2 has CE3 connected to PE1 and CE4
connected to PE2. Site S3 has CE5 connected to PE2. (See
below.) Suppose further that C wants to
"over-provision" each current site, in expectation that the number
of sites will grow to at least 10 in the near future. However, CE4
is only provisioned with 9 DLCIs. (Note that the signalling
mechanism discussed in Section 4 will allow a site to grow in terms
of connectivity to other sites at a later point of time at the cost
of additional signalling, i.e., over- provisioning is not a must
but a recommendation).
Suppose finally that CE0 and CE2 have DLCIs 100 through 109
provisioned; CE1 and CE3 have DLCIs 200 through 209 provisioned; CE4
has DLCIs 107, 209, 265, 301, 414, 555, 654, 777 and 888 provisioned;
and CE5 has DLCIs 417-426.
The following sub-sections detail the configuration that is needed to
provision the above VPN. For the purpose of exposition, we assume
that the customer will connect to the SP with Frame Relay circuits.
While we focus primarily on the configuration that an SP has to do,
we touch upon the configuration requirements of CEs as well. The
main point of contact in CE-PE configuration is that both must agree
on the DLCIs that will be used on the interface connecting them.
If the PE-CE connection is Frame Relay, it is recommended to run LMI
between the PE and CE. For the case of ATM VCs, OAM cells may be
used; for PPP and Cisco HDLC, keepalives may be used directly between
CEs; however, in this case, PEs would not have visibility as to the
liveness of customers circuits.
In case of IP-only Layer 2 interworking, if CE1, attached to PE0,
connects to CE3, attached to PE1, via a L2VPN circuit, the Layer 2
media between CE1 and PE0 is independent of the Layer 2 media
between CE3 and PE1. Each side will run its own Layer 2 specific
link management protocol, e.g., LMI, LCP, etc. PE0 will inform PE1
about the status of its local circuit to CE1 via the circuit status
vector TLV defined in Section 4. Similarly PE1 will inform PE0 about
the status of its local circuit to CE3.
Each CE that belongs to a VPN is given a "CE ID". CE IDs must be
unique in the context of a VPN. For the example, we assume that the
CE ID for CE-k is k.
Each CE is configured to communicate with its corresponding PE with
the set of DLCIs given above; for example, CE0 is configured with
DLCIs 100 through 109. In general, a CE is configured with a list of
circuits, all with the same Layer 2 encapsulation type, e.g., DLCIs,
VCIs, physical PPP interface etc. (IP-only Layer 2 interworking
allows a mix of Layer 2 encapsulation types). The size of this list/
set determines the number of remote CEs a given CE can communicate
with. Denote the size of this list/set as the CE's range. A CE's
range must be at least the number of remote CEs that the CE will
connect to in a given VPN; if the range exceeds this, then the CE is
over-provisioned, in anticipation of growth of the VPN.
Each CE also "knows" which DLCI connects it to each other CE. The
methodology followed in this example is to use the CE ID of the other
CE as an index into the DLCI list this CE has (with zero-based
indexing, i.e., 0 is the first index). For example, CE0 is connected
to CE3 through its fourth DLCI, 103; CE4 is connected to CE2 by the
third DLCI in its list, namely 265. This is just the methodology
used in the example below; the actual methodology used to pick the
DLCI to be used is a local matter; the key factor is that CE-k may
communicate with CE-m using a different DLCI from the DLCI that CE-m
uses to communicate to CE-k, i.e., the SP network effectively acts as
a giant Frame Relay switch. This is very important, as it decouples
the DLCIs used at each CE site, making for much simpler provisioning.
Each PE is configured with the VPNs in which it participates. Each
VPN is associated with one or more Route Target communities
which serve to define the topology of the
VPN. For each VPN, the PE must determine a Route Distinguisher
(RD) to use; this may either be configured or chosen by the PE.
RDs do not have to be unique across the VPN. For each CE attached
to the PE in a given VPN, the PE must know the set of virtual
circuits (DLCI, VCI/VPI or VLAN) connecting it to the CE, and a CE
ID identifying the CE within the VPN. CE IDs must be unique in the
context of a given VPN.
The first step in adding a new site to a VPN is to pick a new CE ID.
If all current members of the VPN are over-provisioned, i.e., their
range includes the new CE ID, adding the new site is a purely local
task. Otherwise, the sites whose range doesn't include the new CE ID
and wish to communicate directly with the new CE must have their
ranges increased by allocating additional local circuits to
incorporate the new CE ID.
The next step is ensuring that the new site has the required
connectivity. This usually requires adding a new virtual circuit
between the PE and CE; in most cases, this configuration is limited
to the PE in question.
The rest of the configuration is a local matter between the new CE
and the PE to which it is attached.
It bears repeating that the key to making additions easy is over-
provisioning and the algorithm for mapping a CE-id to a DLCI which is
used for connecting to the corresponding CE. However, what is being
over-provisioned is the number of DLCIs/VCIs that connect the CE to
the PE. This is a local matter between the PE and CE, and does not
affect other PEs or CEs.
When a PE is configured with all the required information for a
CE, it advertises to other PEs the fact that it is participating
in a VPN via BGP messages, as per ,
section 3. BGP was chosen as the means for exchanging L2 VPN
information for two reasons: it offers mechanisms for both
auto-discovery and signaling, and allows for operational
convergence, as explained in Section 1. A bonus for using BGP is
a robust inter-AS solution for L2VPNs.
There are two modifications to the formating of messages. The
first is that the set of Encaps Types carried in the L2-info
extended community has been expanded to include those from
. The value of the Encaps Type field
identifies the Layer 2 encapsulation, e.g., ATM, Frame Relay etc.
Encaps TypeDescriptionReference0Reserved-1Frame RelayRFC 44462ATM AAL5 SDU VCC transportRFC 44463ATM transparent cell transportRFC 48164Ethernet (VLAN) Tagged ModeRFC 44485Ethernet Raw ModeRFC 44486Cisco HDLCRFC 46187PPPRFC 46188SONET/SDH Circuit Emulation ServiceRFC 48429ATM n-to-one VCC cell transportRFC 471710ATM n-to-one VPC cell transportRFC 471711IP Layer 2 TransportRFC 303215Frame Relay Port modeRFC 461917Structure-agnostic E1 over packetRFC 455318Structure-agnostic T1 (DS1) over packetRFC 455319VPLSRFC 476120Structure-agnostic T3 (DS3) over packetRFC 455321Nx64kbit/s Basic Service using Structure-awareRFC 508625Frame Relay DLCIRFC 461940Structure-agnostic E3 over packetRFC 455341 (1)Octet-aligned payload for Structure-agnostic DS1 circuitsRFC 455342 (2)E1 Nx64kbit/s with CAS using Structure-awareRFC 508643DS1 (ESF) Nx64kbit/s with CAS using Structure-awareRFC 508644DS1 (SF) Nx64kbit/s with CAS using Structure-awareRFC 5086
Note (1): Allocation of a separate code point for Encaps Type
eliminates the need for TDM payload size.
Note (2): Having separate code points for Encaps Types 42-44
allows specifying the trunk framing (i.e, E1, T1 ESF or T1 SF)
with CAS.
The second is the introduction of TLVs (Type-Length-Value
triplets) in the VPLS NLRI. L2VPN TLVs can be added to extend
the information carried in the NLRI, using the format shown in
. In L2VPN TLVs, Type is 1 octet, Length
is 2 octets and represents the size of the Value field in bits.
TLV TypeDescription1Circuit Status Vector
This sub-TLV carries the status of a L2VPN PVC between a pair of
PEs. Note that a L2VPN PVC is bidirectional, composed of two
simplex connection going in opposite directions. A simplex
connection consists of the 3 segments: 1) the local access
circuit between the source CE and the ingress PE, 2) the tunnel
LSP between the ingress and egress PEs, and 3) the access
circuit between the egress PE and the destination CE.
To monitor the status of a PVC, a PE needs to monitor the status of
both simplex connections. Since it knows that status of its access
circuit, and the status of the tunnel towards the remote PE, it can
inform the remote PE of these two. Similarly, the remote PE can
inform the status of its access circuit to its local CE and the
status of the tunnel to the first PE. Combining the local and the
remote information, a PE can determine the status of a PVC.
The basic unit of advertisement in L2VPN for a given CE is a label-
block. Each label within a label-block corresponds to a PVC on the
CE. The local status information for all PVCs corresponding to a
label-block is advertised along with the NLRI for the label-block
using the status vector TLV. The Type field of this TLV is 1. The
Length field of the TLV specifies the length of the value field in
bits. The Value field of this TLV is a bit-vector, each bit of which
indicates the status of the PVC associated with the corresponding
label in the label-block. Bit value 0 corresponds to the PVC
associated with the first label in the label block, and indicates
that the local circuit and the tunnel LSP to the remote PE is up,
while a value of 1 indicates that either or both of them are down.
The Value field is padded to the nearest octet boundary.
If PE A receives a VPLS NLRI, while selecting a label from a
label-block (advertised by PE B, for remote CE m, and VPN X) for
one of its local CE n (in VPN X) can also determine the status of
the corresponding PVC (between CE n and CE m) by looking at the
appropriate bit in the circuit status vector.
In the above, we assumed for simplicity that the VPN was a full mesh.
To allow for more general VPN topologies, a mechanism based on
filtering on BGP extended communities can be used.
As defined so far in this document, all CE-PE connections for a given
Layer 2 VPN must use the same Layer 2 encapsulation, e.g., they must
all be Frame Relay. This is often a burdensome restriction. One
answer is to use an existing Layer 2 interworking mechanism, for
example, Frame Relay-ATM interworking.
In this document, we take a different approach: we postulate that the
network Layer is IP, and base Layer 2 interworking on that. Thus,
one can choose between pure Layer 2 VPNs, with a stringent Layer 2
restriction but with Layer 3 independence, or a Layer 2 interworking
VPNs, where there is no restriction on Layer 2, but Layer 3 must be
IP. Of course, a PE may choose to implement Frame Relay-ATM
interworking. For example, an ATM Layer 2 VPN could have some CEs
connect via Frame Relay links, if their PE could translate Frame
Relay to ATM transparent to the rest of the VPN. This would be
private to the CE-PE connection, and such a course is outside the
scope of this document.
For Layer 2 interworking as defined here, when an IP packet arrives
at a PE, its Layer 2 address is noted, then all Layer 2 overhead is
stripped, leaving just the IP packet. Then, a VPN label is added,
and the packet is encapsulated in the PE-PE tunnel (as required by
the tunnel technology). Finally, the packet is forwarded. Note that
the forwarding decision is made on the basis of the Layer 2
information, not the IP header. At the egress, the VPN label
determines to which CE the packet must be sent, and over which
virtual circuit; from this, the egress PE can also determine the
Layer 2 encapsulation to place on the packet once the VPN label is
stripped.
An added benefit of restricting interworking to IP only as the Layer
3 technology is that the provider's network can provide IP Diffserv
or any other IP based QOS mechanism to the L2VPN customer. The
ingress PE can set up IP/TCP/UDP based classifiers to do DiffServ
marking, and other functions like policing and shaping on the L2
circuits of the VPN customer. Note the division of labor: the CE
determines the destination CE, and encodes that in the Layer 2
address. The ingress PE thus determines the egress PE and VPN label
based on the Layer 2 address supplied by the CE, but the ingress PE
can choose the tunnel to reach the egress PE (in the case that there
are different tunnels for each CoS/DiffServ code point), or the CoS
bits to place in the tunnel (in the case where a single tunnel
carries multiple CoS/DiffServ code points) based on its own
classification of the packet.
When a packet arrives at a PE from a CE in a Layer 2 VPN, the Layer 2
address of the packet identifies to which other CE the packet is
destined. The procedure outlined above installs a route that maps
the Layer 2 address to a tunnel (which identifies the PE to which the
destination CE is attached) and a VPN label (which identifies the
destination CE). If the egress PE is the same as the ingress PE, no
tunnel or VPN label is needed.
The packet may then be modified (depending on the Layer 2
encapsulation). In case of IP-only Layer 2 interworking, the Layer 2
header is completely stripped off till the IP header. Then, a VPN
label and tunnel encapsulation are added as specified by the route
described above, and the packet is sent to the egress PE.
If the egress PE is the same as the ingress, the packet "arrives"
with no labels. Otherwise, the packet arrives with the VPN label,
which is used to determine which CE is the destination CE. The
packet is restored to a fully-formed Layer 2 packet, and then sent to
the CE.
This document requires that the Layer 2 MTU configured on all the
access circuits connecting CEs to PEs in a L2VPN be the same. This
can be ensured by passing the configured Layer 2 MTU in the Layer2-
info extended community when advertising L2VPN label-blocks. On
receiving L2VPN label-block from remote PEs in a VPN, the MTU value
carried in the Layer2-info extendend community should be compared
against the configured value for the VPN. If they don't match, then
the label-block should be ignored.
The MTU on the Layer 2 access links MUST be chosen such that the size
of the L2 frames plus the L2VPN header does not exceed the MTU of the
SP network. Layer 2 frames that exceed the MTU after encapsulation
MUST be dropped. For the case of IP-only Layer 2 interworking the IP
MTU on the Layer 2 access link must be chosen such that the size of
the IP packet and the L2VPN header does not exceed the MTU of the SP
network.
The modification to the Layer 2 frame depends on the Layer 2 type.
This document requires that the encapsulation methods used in
transporting of Layer 2 frames over tunnels be the same as
described in , ,
, and , except in
the case of IP-only Layer 2 Interworking which is described next.
At the ingress PE, an L2 frame's L2 header is completely stripped
off and is carried over as an IP packet within the SP network
(). The forwarding decision is still based
on the L2 address of the incoming L2 frame. At the egress PE, the
IP packet is encapsulated back in an L2 frame and transported over
to the destination CE. The forwarding decision at the egress PE is
based on the VPN label as before. The L2 technology between egress
PE and CE is independent of the L2 technology between ingress PE
and CE.
RFC 4761, on which this document is based, has a detailed
discussion of security considerations. As in RFC 4761, the focus
here is the privacy of customer VPN data (as opposed to
confidentiality, integrity, or authentication of said data); to
achieve the latter, one can use the methods suggested in RFC 4761.
The techniques described in RFC 4761 for securing the control
plane and protecting the forwarding path apply equally to L2 VPNs,
as do the remarks regarding multi-AS operation. The mitigation
strategies and the analogies with also
apply here.
RFC 4761 perhaps should have discussed Denial of Service attacks
based on the fact that VPLS PEs have to learn MAC addresses and
replicate packets (for flooding and multicast). However, those
considerations don't apply here, as neither of those actions are
required of PEs implementing the procedures in this document.
The authors would like to thank Chaitanya Kodeboyina, Dennis
Ferguson, Der-Hwa Gan, Dave Katz, Nischal Sheth, John Stewart, and
Paul Traina for the enlightening discussions that helped shape the
ideas presented here, and Ross Callon for his valuable comments.
The idea of using extended communities for more general
connectivity of a Layer 2 VPN was a contribution by Yakov Rekhter,
who also gave many useful comments on the text; many thanks to
him.
IANA is requested to create two new registries: the first is for
the one-octet Encaps Type field of the L2-info extended community.
The name of the registry is "BGP L2 Encapsulation Types"; the values
already allocated are in of
. The allocation policy for new entries
up to and including value 127 is "Expert Review". The
allocation policy for values 128 through 251 is "First Come First
Served". The values from 252 through 255 are for "Experimental
Use".
The second registry is for the one-octet Type field of the TLVs of
the VPLS NLRI. The name of the registry is "BGP L2 TLV Types";
the sole allocated value is in of
. The allocation policy for new entries
up to and including value 127 is "Expert Review". The
allocation policy for values 128 through 251 is "First Come First
Served". The values from 252 through 255 are for "Experimental
Use".
Building and Managing Virtual Private NetworksWiley Computer Publishing